KR100850118B1 - Photolithography equipment and Method for forming a pattern using thereof - Google Patents

Abstract

The photolithographic apparatus of the present invention includes a light source 12 for providing light, an angle adjustment mirror 14 for adjusting an angle of light provided from the light source 12, and light reflected from the angle adjustment mirror 14. A condenser lens 16 for condensation and transmission, a reticle stage 20 in which a mask 18 is fixed to implement sample patterning using light transmitted through the condensation lens 16, and the sample image. The wafer stage 40 fixedly positioned so that the wafer forming the pattern is positioned, and the light passing through the mask 18 is transmitted through the projection lens 42 so that the image of the mask 18 is adjusted to a predetermined setting. It consists of a micro concave lens 30 provided between the mask 18 and the wafer stage 40 so as to reach the wafer, so that the desired shape is applied to the entire area of the wafer at once without moving the mask and the wafer substrate. The desired pattern can be formed at once, eliminating the need for a series of devices that need to move the mask or wafer stage. This prevents pattern misalignment and eliminates the need to align with advanced step patterns. Has an effect.

Photolithography, Micro Concave Lenses, Mask and Wafer Stage Movement

Description

Photolithography equipment and method for forming a pattern using

1 is a schematic operation diagram of a conventional step-and-repeat photolithography apparatus,

2 is a schematic operation diagram of a step-and-scan photolithography apparatus;

3 is a schematic view showing the configuration of a photolithography apparatus according to a preferred embodiment of the present invention,

4 is a detailed view in which a mask pattern projecting the microlens of the present 3 is patterned on a wafer.

<Description of the code | symbol about the principal part of drawing>

12: illumination optics 14: angle adjustment mirror

16 condensing lens 18 reticle

20: reticle stage 30: micro concave lens

40: wafer stage 41: projection lens

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a next generation pattern formation method using a lithography apparatus of a photo process in a semiconductor manufacturing process. More particularly, a mask and a wafer used to implement patterning may be used to perform micro concave lenses without moving a stage. The present invention relates to a photolithography apparatus and a pattern forming method using the same, by which a desired pattern can be obtained in the entire wafer through one operation.

As is well known, the technology of semiconductors is becoming more refined, and thus photolithography (core) technology is the core, and the trend of semiconductor technology is the same as the technology trend and direction of photolithography process.

Such photolithography uses a light to position a mask of a pattern on which a desired integrated circuit is drawn on a photoresist-coated wafer, and then irradiates a light source onto a wafer prepared in the shape of a mask. It is the core process technology of the semiconductor to form a pattern on the core, and the core technology of the photo process is the utilization of light energy.

After the photoresist is evenly coated on the semiconductor wafer silicon substrate, a mask or reticle on which the desired pattern is designed is placed on the wafer. At this time, an image to be patterned for precise operation and a mark for aligning positions with other reticles are engraved on the wafer and the mask. When a light source of a laser beam or a mercury arc lamp is passed through a patterned mask and irradiated onto the wafer on which the sensitizer is applied, an image of the mask pattern is generated in the resist. At this time, the resist is exposed using a solution such as a solution-based developer or plasma etching to selectively remove a desired portion (or non-exposed portion) to generate a patterned resist through a mask. The technology to date is called a photo process. The patterned resist pattern is then used as a mask for etching. The problems faced by lithographic technology during the device process are:

As line widths become finer, high-speed operation and lower power driving are possible, and semiconductor processes are moving toward realizing fine line widths. However, the biggest problem in an exposure system using light as a light source is that as the line width becomes smaller, the diffraction phenomenon of the light becomes intensified. This causes a process error, leading to degradation of the device performance.

The most fundamental way to solve this problem is to use a light source whose light wavelength is smaller than the pattern size. Another method is projection lithography, which uses a reduction lens between the mask and the substrate, using a low wavelength light source. By using a reduction lens, a precise pattern can be obtained even with a light source having a low wavelength band, and the diffraction phenomenon of the light source on the mask can be prevented.

Also, in lithography technology, one of the important variables as well as the light source is a photo mask that serves as the original pattern of the pattern, and the accuracy of the resulting pattern should be minimized and minimized from the design value.

Therefore, in the photo process, measurements are performed at each process from the first process to the last photo process, and the out-of-process value is corrected through recalibration or rework. In the exposure step, the exposure is performed on a wafer through a device called a stepper or a scanner. Two methods are currently used.

First, as shown in FIG. 1, as a step and repeat method, a reticle stage is fixed, and only a wafer stage is moved to expose (batch exposure).

Second, as shown in FIG. 2, as the step and scan method, when the reticle stage and the wafer stage are moved simultaneously, and the reticle stage is in the positive direction in an exposure-proceeding manner, the wafer stage moves in the negative direction. will be.

Both of these methods require a series of movements in which the reticle stage or the wafer stage must be moved according to the exposure method in order to use the pattern designed on the reticle on the wafer, and the overlay to prevent the distortion that is very likely to occur at this time (Overlay) Alignment, that is, after the initial step progression, the operation is performed to align the alignment with the advanced step pattern in the next step progression.

However, in the conventional photo equipment, in the case of a method of fixing a mask mount such as a reticle or a mask stage and moving only the wafer stage to perform exposure (batch exposure), this is the current problem when patterning is implemented on a wafer. There is a problem that an alignment miss occurs, and the reticle stage and the wafer stage move at the same time so that the exposure progresses. If the reticle stage is in the positive direction, the wafer stage moves in the negative direction as an initial step. There was a problem that alignment was to be performed with the advanced step pattern during the next step progression.

Accordingly, an object of the present invention is to provide a lithographic apparatus and a pattern forming method using the same, by implementing a desired pattern on the entire wafer at a time without moving the wafer and the mask by the pattern projection method through the micro multi-purpose lens.

The photolithographic apparatus of the present invention for achieving the above object comprises an illumination optical unit for optically illuminating the light from the light source, an angle adjustment mirror for adjusting the angle of light irradiated from the illumination optical unit, and in the angle adjustment mirror A condensation lens that condenses and transmits the reflected light, a reticle stage having a mask fixed to implement patterning by using the light passing through the condensation lens, a wafer stage on which a wafer on which the patterning is implemented is located, and the mask It consists of a micro concave lens provided between the mask and the wafer stage so that the image of the mask is patterned on the wafer by passing the light passing through.

In addition, in the pattern formation method using the photolithographic apparatus, the present invention enables the micro-concave lens to fit the desired size and number at a time without moving the mask and wafer stage.

In the present invention, the micro-concave lens is laser processing the quartz plate to implement a concave lens, the size and depth is preferably modified to suit the exposure process, the exposure process than the number that can implement the desired patterning Up and down adjustment is possible to make more than possible to optimize the image formed by moving the focus.

According to the present invention, since the desired pattern can be formed in the desired shape at once in the entire area of the wafer without moving the mask and the wafer substrate, a series of devices that need to move the mask or the wafer stage are not necessary. The pattern misalignment is prevented and the overlay alignment, that is, the alignment of the advanced step pattern with the advanced step pattern after the initial step progression becomes unnecessary, thus contributing to the process simplification.

The above and other objects and various advantages of the present invention will become more apparent from the preferred embodiments of the present invention described below with reference to the accompanying drawings by those skilled in the art.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 shows a configuration of a photolithography apparatus according to a preferred embodiment of the present invention.

As shown in FIG. 3, the photolithographic apparatus of the present invention includes an optical illumination unit 12 for optically illuminating light from a light source (not shown) that provides light, and the illumination optical unit 12 irradiated from the illumination optical unit 12. An angle adjusting mirror 14 for adjusting the angle of light, a condenser lens 16 for condensing and transmitting the light reflected from the angle adjusting mirror 14, and a light passing through the condensing lens 16; Reticle stage 20 having mask 18 fixed to implement patterning using light, wafer stage 40 fixed to position wafer where the patterning is implemented, and light passing through mask 18 The micro lens 30 is disposed between the mask 18 and the wafer stage 40 to transmit the light through the projection lens 42 to pattern the image of the mask 18 on the wafer.

The micro lens 30 implements a concave lens by laser processing a quartz plate, which is generally used as a mask material, and the light provided from the light source 12 passes through the photo mask 18 to form a projection lens ( When reaching the micro concave lens 30 through 42, light is transmitted according to the characteristics of the concave lens so that the image of the mask 18 is deformed according to the setting of the concave lens, i. Thus patterned on the wafer.

To this end, in the present invention, the micro-concave lens 30 may be adjusted up and down so that the patterning required in the corresponding exposure process can be manufactured in excess of the number that can be realized.

According to the photolithography apparatus of the present invention configured as described above, the light provided from the light source 12 passes through the photo mask 18 and reaches the micro concave lens 30 through the projection lens 42. The mask pattern of the mask 18 having transmitted the light according to the characteristics of the micro concave lens 30 is formed on the wafer as shown in FIG. 4 according to the size and depth according to the setting of the micro concave lens through the projection lens 42. Patterned 44 is made.

In the above description has been described by presenting a preferred embodiment of the present invention, but the present invention is not necessarily limited to this, and those skilled in the art to which the present invention pertains within a range without departing from the technical spirit of the present invention It will be readily understood that branch substitutions, modifications and variations are possible.

As described above, according to the present invention, since the desired pattern can be formed in the desired shape at once in the entire area of the wafer without moving the mask and the wafer substrate, there is no need for a series of devices that need to move the mask or wafer stage. In addition, the pattern distortion phenomenon, which is a conventional problem, is prevented, and the overlay alignment, that is, the work of aligning the advanced step pattern with the advanced step pattern during the progress of the next step after the initial step progression is unnecessary, thereby contributing to the process simplification.

Claims (4)

In a photolithography apparatus, An illumination optics optically illuminating the light from the light source providing the light; An angle adjusting mirror for adjusting an angle of light irradiated from the illumination optical unit; A condensation lens for condensing and transmitting the light reflected from the angle adjusting mirror; A reticle stage provided with a mask to implement patterning by using the light transmitted through the condensation lens; A wafer stage on which the wafer on which the patterning is implemented is located; A micro concave lens disposed between the mask and the wafer stage so as to transmit light passing through the mask to pattern the image of the mask on the wafer. Photolithography apparatus. The method of claim 1, The micro concave lens is laser processed quartz plate to implement a concave lens, the size and depth is characterized in that it is modified to suit the exposure process Photolithography apparatus. The method of claim 1, The micro-concave lens is a photolithography apparatus characterized by optimizing the image formed by moving the focus by the vertical adjustment is possible so that the exposure process is capable of manufacturing more than the desired number of patterning. In the pattern formation method using a photolithography apparatus, A pattern forming method in which the patterning can be made to be desired at a time by the micro-concave lens without moving the mask and wafer stage using the photolithography apparatus according to claim 1.

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